Lever assembly for positive lock adjustable seat post

ABSTRACT

A method and apparatus for a seat post assembly that is adjustable to an upper, intermediate, and lower seat post position using a locking member and a sleeve member coupled to an actuator for securing and releasing an inner tube with respect to an outer tube. The actuator may move the sleeve member to release the locking member from engagement with the outer tube to adjust the inner tube and thus the seat post assembly to the upper, intermediate, or lower seat post positions. The actuator and the sleeve may be biased into an initial position that urges the locking member into engagement with outer tube to lock the inner tube to the outer tube.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application is a continuation application of and claims thebenefit of co-pending U.S. patent application Ser. No. 15/593,020, filedMay 11, 2017, entitled, “LEVER ASSEMBLY FOR POSITIVE LOCK ADJUSTABLESEATPOST”, by Laird et al., assigned to the assignee of the presentapplication, which is incorporated herein in its entirety by referencethereto.

The patent application Ser. No. 15/593,020 is a continuation applicationof and claims the benefit of U.S. patent application Ser. No.14/330,996, filed Jul. 14, 2014, now U.S. Pat. No. 9,650,094, entitled,“LEVER ASSEMBLY FOR POSITIVE LOCK ADJUSTABLE SEATPOST”, by Laird et al.,assigned to the assignee of the present application, which isincorporated herein in its entirety by reference thereto.

The patent application Ser. No. 14/330,996 is a divisional applicationof and claims the benefit of U.S. patent application Ser. No.13/176,336, filed Jul. 5, 2011, now U.S. Pat. No. 8,814,109, entitled,“POSITIVE LOCK ADJUSTABLE SEAT POST”, by Laird et al., assigned to theassignee of the present application, which is incorporated herein in itsentirety by reference thereto.

The U.S. patent application Ser. No. 13/176,336 claims priority to andbenefit of U.S. provisional patent application 61/361,376, filed Jul. 2,2010, entitled “POSITIVE LOCK ADJUSTABLE SEAT POST”, by Laird et al.,assigned to the assignee of the present application, which isincorporated herein in its entirety by reference thereto.

BACKGROUND OF THE INVENTION

Field of the Invention

Embodiments of the invention generally relate to a seat support assemblyfor a vehicle. More specifically, embodiments of the invention relate toa height adjustable seat support. Embodiments of the invention furtherrelate to a height adjustable seat post for a bicycle.

Description of the Related Art

Most modern bicycles include a rigid seat post that may be movedrelative to the bicycle frame and clamped at a desired height relativeto the frame for accommodating different sizes of riders and differentrider styles. Generally, adjusting the seat post height in the framerequires that the rider be off the bicycle and/or may requires asignificant amount of time and manipulation of the bicycle to achievethe desired seat height.

Therefore, there is a need for new and improved adjustable seat postdesigns and methods of use.

SUMMARY OF THE INVENTION

In one embodiment, a seat post assembly may comprise an first or outertube; a second or inner tube axially movable within the outer tube; alocking member coupled to the inner tube and operable to lock the innertube to the outer tube at a first location and at a second locationspaced apart along the axial length of the outer tube; and an actuatoroperable to secure the locking member into engagement with the outertube at the first and second locations, and operable to release thelocking member from engagement with the outer tube to move the lockingmember from the first location to the second location.

In one embodiment, a method of adjusting a seat post assembly that hasan inner tube axially movable within an outer tube may comprise lockingthe inner tube to the outer tube at a first location using a lockingmember that is coupled to the tube; securing the locking member intoengagement with the outer tube using an actuator to lock the inner tubeto the outer tube; moving the actuator against the bias of a biasingmember to release the locking member from engagement with the outer tubeat the first location; and moving the inner tube from the first locationto a second location after releasing the locking member.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features can be understoodin detail, a more particular description of the invention, brieflysummarized above, may be had by reference to embodiments, some of whichare illustrated in the appended drawings. It is to be noted, however,that the appended drawings illustrate only typical embodiments of thisinvention and are therefore not to be considered limiting of its scope,for the invention may admit to other equally effective embodiments.

FIGS. 1A-1C illustrate a seat post assembly.

FIGS. 2A-2E illustrate an inner tube of the seat post assembly.

FIGS. 3A-3C illustrate an outer tube of the seat post assembly.

FIGS. 4A-4C illustrate the seat post assembly when locked in an extendedor upper seat post position.

FIGS. 5A-5H illustrate cross sectional views of the seat post assemblyof FIGS. 4A-4C.

FIGS. 6A-6C illustrate the seat post assembly when actuated for movementinto an intermediate seat post position.

FIGS. 7A-7H illustrate cross sectional views of the seat post assemblyof FIGS. 6A-6C.

FIGS. 8A-8C illustrate the seat post assembly when locked in theintermediate seat post position.

FIGS. 9A-9H illustrate cross sectional views of the seat post assemblyof FIGS. 8A-8C.

FIGS. 10A-10C illustrate the seat post assembly when actuated formovement into a compressed or lower seat post position.

FIGS. 11A-11G illustrate cross sectional views of the seat post assemblyof FIGS. 10A-10C.

FIGS. 12A-12C illustrate the seat post assembly when locked in thecompressed or lower seat post position.

FIGS. 13A-13C and 14A-14D illustrate cross sectional views of the seatpost assembly of FIGS. 12A-12C.

FIGS. 15A-15G illustrate the seat post assembly prior to being locked inthe compressed or lower seat post position.

FIGS. 16A-16J illustrate the seat post assembly when locked in anextended or upper seat post position.

FIGS. 17A-17J illustrate the seat post assembly when actuated formovement into an intermediate seat post position.

FIGS. 18A-18J illustrate the seat post assembly when locked in theintermediate seat post position.

FIGS. 19A-19J illustrate the seat post assembly when actuated formovement into a compressed or lower seat post position.

FIGS. 20A-20J illustrate the seat post assembly when locked in thecompressed or lower seat post position.

FIGS. 21A-21E illustrate a lever assembly.

DETAILED DESCRIPTION

FIGS. 1A-1C illustrate a seat post assembly 100 for a vehicle, such as abicycle. FIGS. 2A-2E and 3A-3C illustrate an inner tube 110 and an outertube 120, respectively, of the seat post assembly 100. The seat postassembly 100 includes the inner tube 110 telescopically received withinthe outer tube 120. An upper end of the inner tube 110 includes a seatretainer 130 for retaining a selected riding saddle or bicycle seat. Theinner tube 110 further includes a cable guide 160 and a lever 140 fixedthereto and pivotable about a pin 150 (as will be described in greaterdetail herein). A lower end of the outer tube 120 includes a fill valve170, such as a gas fill valve of any suitable type, including forexample a Schrader valve or a Presta valve.

In one embodiment, the inner tube 110 includes a thick wall section 180in a first plane and a thin wall section 190 in a second plane where theresult is a substantially oval inner space cross section. Theselectively tailored wall section results in adequate strength andreduced overall weight. The lower end of the inner tube 110 includes oneor more upper holes 195 and one or more lower holes 175 radiallyextending through the wall thickness. The upper and lower holes 195, 175may be axially and/or radially offset relative to each other about theouter diameter of the inner tube 110. A plurality of keyways 185 arealso included on an exterior of the inner tube 110 above the upper andlower holes 195, 175.

The outer tube 120 includes an upper snap ring recess 121 and a lowersnap ring recess 122 for receiving one or more snap rings. Section A-Aas illustrated in FIG. 3B shows some interior features of one embodimentof the outer tube 120, including an upper ball lock recess 125, anintermediate ball lock recess 126, and a lower ball lock recess 127,which correspond to an extended or upper seat post position, anintermediate seat post position, and a compressed or lower seat postposition, respectively. Also shown are axial ball tracks 128 for guidingone or more locking members, such as ball members, from the upper seatpost position to the intermediate seat post position.

In one embodiment, the inner tube 110 and/or the outer tube 120 may beformed from solid, forged structures. The inner tube 110 and the seatretainer 130 may be formed integrally as a single piece of material. Oneor more of the other seat post assembly 100 components may be formedintegrally with the inner tube 110 and/or the outer tube 120 reduce thenumber of parts of the assembly. The components of the seat postassembly 100 may be forged as solid, single piece of material structuresto optimize wall thicknesses to achieve desired and/or necessary weightand strength.

FIGS. 4A-4C illustrate one embodiment of the seat post assembly 100locked in the extended or upper seat post position. FIGS. 5A-5Hillustrate cross sectional views of the seat post assembly of FIGS.4A-4C. In all positions, the inner tube 110 is received in the outertube 120 through a sliding seal head/wiper assembly 5. The sealhead/wiper assembly 5 provides a seal and a debris barrier against therelatively smooth (e.g. 32 or 16 rms) outer surface of the inner tube110. The seal head/wiper assembly 5 may include one or more o-rings orseals for sealing between the inner tube 110 and the outer tube 120, oneor more wiper rings for protecting against or occluding debris, and/orone or more snap rings for securing the components within the outer tube120. The seal head/wiper assembly 5 may also provide a seal for a springchamber 10 disposed within the outer tube 120.

Referring to FIG. 5E for example, the extended seat post assembly 100 isheld in position by one or more ball members 20 that are engaged withthe inner tube 110 through the one or more lower holes 175, and theouter tube 120 in the upper ball lock recess 125. The one or more ballmembers 20 are retained in a radially extended position, correspondingto a locked seat post position, by a large diameter portion 30 of asleeve 35. The sleeve 35 is coupled to and axially movable with and byan actuator 34, such as a rod member, which retains the sleeve 35between a biasing member, such as spring 152, and a retainer 37. Thesleeve 35 is slidable in relation to the actuator 34 but againstcompression in the spring 152.

The actuator 34 is axially movable by means of the lever 140, whichpivots about the pin 150, and specifically in one embodiment becausefork arm 145 engages a roll pin 146 that extends through and to eitherside of the actuator 34. When the lever 140 is pulled toward the cableguide 160, by a cable installed there through and attached to the lever140, the fork arm 145 moves in a direction opposite the lever 140 andpulls on the roll pin 146. While one end of the cable passes through thecable guide 160 and attaches to the lever 140, another end of the cableaccording to one embodiment is attached to and operated by a manuallever having an index system for positively corresponding to theextended or upper, intermediate, and compressed or lower seat postpositions. As the roll pin 146 is forced upward, so too is the actuator34, thereby compressing a biasing member, such as spring 151, which maybe positioned between a retainer coupled to the actuator and a shoulderof the inner tube 110. Thus when tension on the cable and correspondingforce on the lever 140 is released, the lever 140 and the actuator 34return to the previous position. Further, as the actuator 34 is movedupward, so too is the sleeve 35 moved upward, thereby moving the largediameter portion 30 up and out from under the one or more ball members20. The actuator 34 may extend outside of the sealed spring chamber 10and is sealed through a chamber bulkhead 36 comprising one or more seals33, such as o-rings, as shown in FIG. 5F for example, and is held from“falling into” the spring chamber 10 by a stop ring 32. A plurality ofkeys 38 mounted to the inner tube 110 in the keyways 185 travel in axialslots 39 formed in the outer tube 120 to maintain relative rotationalorientation of the inner tube 110 and the outer tube 120 and to maintainaxial travel limits of the inner tube 110 within the outer tube 120.

FIGS. 6A-6C illustrate one embodiment of the seat post assembly 100 whenactuated for movement into the intermediate seat post position. FIGS.7A-7H illustrate cross sectional views of the seat post assembly ofFIGS. 6A-6C. FIG. 7E shows that the lever 140 has been pulled by a cablefor example to an intermediate position, and the fork arm 145 has raisedthe roll pin 146 and thus the actuator 34 to a position where the largediameter portion 30 of the sleeve 35 is removed from supporting the oneor more ball members 20, while the one or more ball members 21 remainsupported by the large diameter portion 30. As such, the one or moreball members 20 are free to move from the upper ball lock recess 125 ofthe outer tube 120, and the one or more ball members 21 are free totravel downward along and within the axial ball tracks 128 of the outertube 120. A compressive or downward force (e.g. the weight of a rider)must be applied to a saddle or seat mounted on the seat post assembly100 to cause contraction of the seat post assembly 100 while theactuator 34 is in the intermediate position. This is because a springgas pressure (e.g. 25 psi or 15 to 50 psi) within the spring chamber 10exerts a force tending to extend the seat post assembly 100, which ishow it is extended when actuated.

FIGS. 8A-8C illustrate one embodiment of the seat post assembly 100 whenlocked in the intermediate seat post position. FIGS. 9A-9H illustratecross sectional views of the seat post assembly of FIGS. 8A-8C. Whenlocked in the intermediate position, the one or more ball members 20extend into the intermediate ball lock recess 126 and are supported bythe large diameter portion 30 of the sleeve 35. The sleeve 35 has beenre-positioned with the large diameter portion 30 under or behind both ofthe one or more ball members 20, 21 because the lever 140 has beenreleased and the compression force of the spring 151 has returned theactuator 34 and the sleeve 35 to the lower position relative to theinner tube 110. The one or more ball members 21 traveled axiallydownward in the axial ball tracks 128 and abut a shoulder or the ends129 of the axial ball tracks 128. Such abutment serves as a downwardlimiter thereby providing a positive location and stop for theintermediate seat post position, so long as the lever 140 and theactuator 34 are initially positioned for intermediate travel only.According to one embodiment, the intermediate seat post position cannotbe passed while compressing the seat post assembly 100 so long as thelever 140 is positioned for intermediate travel (e.g. when an operatinglever is for example indexed in the intermediate travel mode). When theone or more ball members 21 are abutting the shoulder or the ends 129 ofthe axial ball tracks 128, the one or more ball members 20 are alignedwith the intermediate ball locking recess 126.

FIGS. 10A-10C illustrate one embodiment of the seat post assembly 100when actuated for movement into the compressed or lower seat postposition. FIGS. 11A-11G illustrate cross sectional views of the seatpost assembly of FIGS. 10A-10C. FIG. 11D shows the lever 140 actuated tofull travel whereby the spring 151 is correspondingly compressed, thelarge diameter portion 30 of the sleeve 35 is removed from beneath orbehind both of the one or more ball members 20, 21, and the inner tube110 is traveling downward within the outer tube 120 by virtue of appliedrider weight and while compressing gas in the spring chamber 10. Whenthe large diameter portion 30 of the sleeve 35 moved from beneath orbehind the one or more ball members 20, 21, this allows the one or moreball members 20 to retract from engagement with the intermediate balllocking recess 126, and allows the one or more ball members 21 toretract from engagement with the shoulder or ends 129 of the axial balltracks 128 to enable the inner tube 110 to move to the compressed orlower seat post position using applied rider weight to the inner tube110.

FIGS. 12A-12C illustrate one embodiment of the seat post assembly 100when locked in the compressed or lower seat post position. FIGS. 13A-13Cand 14A-14D illustrate cross sectional views of the seat post assemblyof FIGS. 12A-12C. FIGS. 13B and 14B illustrate the inner tube 110 fullycompressed into the outer tube 120, and the seat post assembly 100locked in its lowest position. The lever 140 has been released and thespring 151 has returned the actuator 34 relatively downward and thelarge diameter portion 30 of the sleeve 35 to a position under or behindboth the one or more ball members 20, 21. With the seat post assembly100 in the lower position, it may be raised by pulling downward on thelever 140 to full travel at which point the large diameter portion 30 ofthe sleeve 35 is removed from under or behind the one or more ballmembers 20, 21 and the inner tube 110 is pushed upwardly relative to theouter tube 120 by gas pressure within the spring chamber 10.

FIGS. 15A-15E illustrates the seat post assembly 100 during thetransition from the intermediate seat post position to the lower orcompressed seat post position, and after release of the lever 140. Asillustrated in FIG. 15E for example, the propensity against the spring152 leaves a gap 153 until the one or more ball members 20, 21 moveradially outward into the lower ball locking recess 127 upon arrival atthe lower position, as described above with respect to FIGS. 12A-14D.When the one or more ball members 20, 21 arrive at the lower balllocking recess 127, they move radially outward therein with the largediameter portion 30 of the sleeve 35 underneath or behind the one ormore ball members 20, 21 to thereby lock the seat post assembly 100 inthe compressed or lower seat post position.

FIGS. 16A-16J illustrate a seat post assembly 200 for a vehicle, such asa bicycle. The embodiments of the seat post assembly 100 illustrated inFIGS. 1A-15G and described herein may be used with the embodiments ofthe seat post assembly 200 illustrated in FIGS. 16A-21E, and vice versa.The components of the seat post assembly 200 that are similar to thoseof the seat post assembly 100 may include the same reference numeralending but with at “200” series designation. Although referenced in thedrawings, a full description of each component will not be repeatedherein for brevity.

The seat post assembly 200 illustrated in FIGS. 16A-16J is locked in theextended or upper seat post position. The seat post assembly 200includes the inner tube 210 telescopically movable within the outer tube220. The upper end of the inner tube 210 includes the seat retainer 233for retaining a selected riding saddle or bicycle seat. The inner tube210 further includes the cable guide 260, and the lever 240 coupledthereto and pivotable about the pin 250. The lower end of the outer tube220 includes the fill valve 270, such as a gas fill valve of anysuitable type, including for example a Schrader valve or a Presta valve.

One difference of the seat post assembly 200 with respect to the seatpost assembly 100 is the form of the lower end of the inner tube 210. Asillustrated in FIG. 16F for example, the lower end of the inner tube 210includes a plurality of lower holes 275 disposed through the wall of theinner tube 210 for supporting one or more first ball members 219 and oneor more second ball members 221, which are axially and symmetricallypositioned adjacent to each other about the inner tube 210. The axialball tracks 228 are provided along the inner surface of the outer tube220 for guiding the one or more second ball members 221 from the upperseat post position to the intermediate seat post position. The lower endof the inner tube further includes two sets of upper holes 295 axiallyspaced apart and disposed through the wall of the inner tube 210 forsupporting one or more third ball members 223.

Another difference is a second sleeve 231 that is disposed adjacent tothe sleeve 235 having the large diameter portion 230 for urging thefirst and/or second ball members 219, 221 into the upper, intermediate,and/or lower ball lock recesses 225, 226, 227, respectively, which arespaced axially along the length of the outer tube 220. The second sleeve231 is disposed around the actuator 234 and is moveable with the sleeve235 relative to the inner tube 210 and the third ball members 223. Thesecond sleeve 231 includes large diameter portions 241 for urging thethird ball members 223 radially outward into engagement with the keys238, which travel along axial slots 239 formed in the inner surface ofthe outer tube 220. The third ball members 223 are urged into the keys238, which are urged into the axial slots 239 to secure and ensure thatthe inner tube 210 is rotationally locked with the outer tube 220. Thesecond sleeve 231 also includes smaller diameter or tapered portions 242for relieving the engagement between the third ball members 223 and thekeys 238 during axial transition of the seat post assembly between seatpost positions. The plurality of keyways 285 are also included on theexterior of the inner tube 210 for supporting the keys 238.

Finally, in addition to the spring 252 that biases the sleeve 235 towardthe end of the actuator 234, another biasing member, such as spring 254,is positioned between an inner shoulder of the second sleeve 231 and aretainer 256 coupled to the actuator 234 to bias the second sleeve 231toward the sleeve 235 and the end of the actuator 234. The springs 252,254 maintain the sleeves 235, 231 in an initial position with respect tothe first, second, and third ball members 219, 221, 223 when theactuator 234 is not being actuated by the lever 240 and/or when the seatpost assembly 200 is in one of the upper, intermediate, and/or lowerseat post positions. When in the initial position, the large diameterportions 230, 241 of the sleeves 235, 231 are positioned underneath orbehind the first, second, and third ball members 219, 221 and 223,respectively.

As illustrated in FIG. 16E for example, the inner tube 210 is receivedin the outer tube 220 through the sliding seal head/wiper assembly 205,which may provide a seal for the spring chamber 215 disposed within theouter tube 220. The seat post assembly 100 is locked in the extended orupper seat post position by the first ball members 219 that are engagedwith the inner tube 210 through the one or more lower holes 275, and theouter tube 220 in the upper ball lock recess 225. The first ball members219 are retained in a radially extended position, corresponding to thelocked seat post position, by the large diameter portion 230 of thesleeve 235, which is axially movable with and by the actuator 234.

The actuator 234 is axially movable by means of the lever 240, whichpivots about the pin 250, and specifically in one embodiment because thefork arm 245 engages the roll pin 246 that extends through and to eitherside of the actuator 234. When the lever 240 is pulled toward the cableguide 260, by a cable installed there through and attached to the lever240, the fork arm 245 moves in a direction opposite the lever 240 andpulls on the roll pin 246. While one end of the cable passes through thecable guide 260 and attaches to the lever 240, another end of the cableaccording to one embodiment is attached to and operated by a leverassembly 300 (illustrated in FIGS. 21A-21 E for example) having an indexsystem for positively corresponding to the extended or upper,intermediate, and compressed or lower seat post positions. As the rollpin 246 is forced upward, so too is the actuator 234, therebycompressing the spring 251. Thus when tension on the cable andcorresponding force on the lever 240 is released, the lever 240 and theactuator 234 return to the previous initial position. Further, as theactuator 234 is moved upward, so too are the sleeve 235 and the secondsleeve 231 moved upward, thereby moving the large diameter portions 230,241, respectively, up and out from under or behind the first, second,and third ball members 219, 221 and 223, respectively. The actuator 234may extend outside of the sealed spring chamber 215 and is sealedthrough the chamber bulkhead 236 comprising one or more seals, and isheld from “falling into” the spring chamber 215 by the stop ring 232.

The plurality of keys 238 mounted to the inner tube 210 in the keyways285 travel in axial slots 239 formed in the outer tube 220 to maintainrelative rotational orientation of the inner tube 210 and the outer tube220 and to maintain axial travel limits of the inner tube 210 within theouter tube 220. The third ball members 223 may also be urged intocontact with the keys 238 by the large diameter portions 241 of thesecond sleeve 231 when the actuator 234 is in the relaxed or initialposition. When the actuator 234 is actuated, the large diameter portions241 of the second sleeve 231 may be removed from underneath or behindthe third ball members 223 so that they may retract radially inward fromrigid engagement with the keys 238 to facilitate uninhibited and smoothtravel of the inner tube 220 to the different seat post positions.

FIGS. 17A-17D illustrate one embodiment of the seat post assembly 200when actuated for movement into the intermediate seat post position.FIGS. 17E-17J illustrate cross sectional views of the seat post assemblyof FIGS. 17A-D. FIG. 17F shows that the lever 240 has been pulled oractuated to an intermediate position, and the fork arm 245 has raisedthe roll pin 246 and thus the actuator 234 to a position where the largediameter portion 230 of the sleeve 235 is removed from supporting thefirst ball members 219, while the second ball members 221 remainsupported by the large diameter portion 230 but are positioned withinthe axial ball tracks 228. As such, the first ball members 219 are freeto move out of engagement from the upper ball lock recess 225 of theouter tube 220, and the second ball members 221 are free to traveldownward along and within the axial ball tracks 228 of the outer tube220. In addition, the large diameter portions 241 of the second sleeve231 are removed from urging the third ball members 223 into contact withthe keys 238 to facilitate the transition of the seat post assembly 200from the upper seat post position to the intermediate seat postposition. A compressive or downward force (e.g. the weight of a rider)must be applied to the saddle or seat mounted on the seat post assembly200 to cause contraction of the seat post assembly 200 while theactuator 234 is in the actuated intermediate position. This is becausethe spring gas pressure (e.g. 25 psi or 15 to 50 psi) within the springchamber 215 exerts a force tending to extend the seat post assembly 200,which is how it is extended when actuated.

FIGS. 18A-18D illustrate one embodiment of the seat post assembly 200when locked in the intermediate seat post position. FIGS. 18E-18Jillustrate cross sectional views of the seat post assembly of FIGS.18A-D. When locked in the intermediate position, the first and secondball members 219, 221 extend into the intermediate ball lock recess 226and are supported by the large diameter portion 230 of the sleeve 235.The sleeve 235 has been re-positioned with the large diameter portion230 under or behind both of the first and second ball members 219, 221because the lever 240 has been released and the compression force of thespring 251 has returned the actuator 234 and the sleeve 235 to the lowerinitial position relative to the inner tube 210. The second ball members221 traveled axially downward in the axial ball tracks 228, which end inthe intermediate ball lock recess 226, thereby providing a positivelocation and stop for the intermediate seat post position, so long asthe lever 240 and the actuator 234 are initially positioned forintermediate travel only. According to one embodiment, the intermediateseat post position cannot be passed while compressing the seat postassembly 200 so long as the lever 240 is positioned for intermediatetravel (e.g. when an operating lever is for example indexed in theintermediate travel mode). When the second ball members 221 exit theaxial ball tracks 228, they are aligned with the intermediate balllocking recess 226.

FIGS. 19A-19D illustrate one embodiment of the seat post assembly 200when actuated for movement into the compressed or lower seat postposition. FIGS. 19E-19J illustrate cross sectional views of the seatpost assembly of FIGS. 19A-D. FIG. 17F shows the lever 240 actuated tofull travel whereby the spring 251 is correspondingly compressed, thelarge diameter portions 230, 241 of the sleeves 235, 231 are removedfrom beneath or behind the first, second, and third ball members 219,221, 223, and the inner tube 210 is traveling downward within the outertube 220 by virtue of applied rider weight and while compressing gas inthe spring chamber 215.

FIGS. 20A-20D illustrate one embodiment of the seat post assembly 200when locked in the compressed or lower seat post position. FIGS. 20E-20Jillustrate cross sectional views of the seat post assembly of FIGS.20A-D. FIG. 20F shows that the lever 240 has been released and thespring 251 has returned the actuator 234 relatively downward and thelarge diameter portions 230, 241 of the sleeves 235, 231 to a positionunder or behind both the first, second, and third ball members 219, 221,223. When the first and second ball members 219, 221 arrive at the lowerball lock recess 227, they move radially outward therein with the largediameter portion 230 of the sleeve 235 underneath or behind the firstand second ball members 219, 221 to thereby lock the seat post assembly200 in the lower seat post position.

With the seat post assembly 200 in the compressed or lower seat postposition, it may be raised by pulling downward on the lever 240 to fulltravel at which point the large diameter portions 230, 241 of thesleeves 235, 231 are removed from under or behind the first, second, andthird ball members 219, 221, 223 and the inner tube 210 is pushedupwardly relative to the outer tube 220 by gas pressure within thespring chamber 215.

FIGS. 21A-21E illustrate one embodiment of a lever assembly 300 that canbe coupled to the levers 140, 240 by a single cable 309 or at least onecable 309 for operating the seat post assemblies 100, 200 as describedherein. The lever assembly 300 may be coupled to the handlebar of abicycle for manual operation by the user. The lever assembly 300 mayinclude a support member 310 for supporting a housing 320, whichrotatably supports a first lever 330 and a second lever 340. Singlecable 309 or at least one cable 309 may be attached to at least thefirst lever 330. One or more fasteners 311, 312 may be used to easilyand quickly connect and disconnect the lever assembly 300 to thebicycle. In one embodiment, the handlebar of a bicycle may be disposedthrough an opening 315 of the support member 310 at a desired position,and the housing 320 may be adjustably secured to the support member 310at one or more locations 317 depending on user preference. Asillustrated in FIGS. 21A and 21B, the lever assembly 300 is adjustablefor operation with both right-handed and left-handed users. The leverassembly 300, and in particular the housing 320 can be flipped, invertedor turned upside down from an upright position with respect to thesupport member 310 to easily convert the lever assembly 300 for use onthe right or left hand side of the bicycle handlebar, and for use aboveor below the bicycle handlebar, using a single fastener.

As illustrated in FIGS. 21C-21E, the first and second levers 330, 340are rotatably coupled to the housing 320 and are movable to one or morepreset positions that correspond to the extended or upper, intermediate,and compressed or lower seat post positions. The first lever 330 may belonger than the second lever 340, and a portion of the second lever 340overlaps a portion of the first lever 330. The first lever 330 (orprimary lever) may be configured to rotate through a first angulardistance to pull the full amount of cable (e.g. compare FIG. 21C to FIG.21E) to actuate the actuators 34, 234 as described above to their fulltravel to move the seat post assemblies 100, 200 to the compressed orlower seat post position, or to release from the lowest position to movethe seat post assemblies 100, 200 to the extended or upper seat postposition. The second lever 340 (or secondary lever) may only move orrotate through a portion such as one-half of the first angular distanceand pulls one-half of the cable (e.g. compare FIG. 21C to FIGS. 21D, E).FIG. 21C illustrates the lever assembly 300 in the normal position. Thesecond lever 340 may be pushed or moved halfway through the firstangular distance from the position in FIG. 21C to the position in FIG.21D until it reaches a hard-stop (such as a portion of the housing 320);in this way the second lever 340 is only able to travel a smallerangular distance than the first lever 330. By virtue of theaforementioned overlap between the two levers 330, 340, a force appliedto the second lever 340 in one direction causes the first lever 330 tomove in the same direction at the same time, and therefore pull thecable to effect seat post adjustment. Following that the user may locate(e.g. with the thumb) another part of the first lever 330, such as thelonger part of the first lever 330 projecting beyond the end of thesecond lever 340 and then the first lever 330 may be pushed or movedfurther through the first angular distance to the full position in FIG.21E to go to full travel. The lever assembly 300 may therefore allow theuser to easily find the intermediate position by pushing the secondlever 340 until it contacts its hardstop halfway through the rotationaltravel of the first lever 330. This action will cause the movement ofthe first lever 330 halfway through its rotational travel, ensuring thatthe correct amount of cable is pulled to actuate the lever 140 forexample as described above to move the seat post assemblies 100, 200 tothe intermediate seat post position. As described above, following thatthe first lever 330 may be pushed beyond the angular range of the secondlever 340 to move the seat post assemblies 100, 200 to the fullyextended and/or compressed positions. When the seat post assemblies 100,200 are in the extended or upper seat post position, the first andsecond levers 330, 340 may be in the position illustrated in FIG. 21C,which position is ready for operation to adjust seat post assemblies100, 200 to the intermediate and/or lower seat post positions. In theother direction, the first lever 330 may be pulled back (such as by theuser and/or by spring/cable return) until the overlapping portions comeinto abutment with one another, signaling to the user that the correctposition has been reached to adjust the seat post assemblies 100, 200back to the intermediate seat post position. If the user desires theseat post to be returned to the fully compressed position the firstlever 330 can simply be pulled all the way back to the position shown inFIG. 21D. In doing so, and by virtue of the lever overlap, the secondlever 340 is also returned to the initial position shown in that Figure,ready for the next seat post adjustment. This arrangement ensures thatthe first lever 330 cannot be moved back to the initial position (FIG.21D) without moving the second lever 340 back at the same time. Althoughdescribed herein for use with the seat post assemblies 100, 200, thelever assembly 300 may be used with other vehicle systems, such as avehicle suspension system. In one embodiment, the lever assembly 300 maybe operable to control the actuation and/or adjustment of a bicyclesuspension system.

In one embodiment, a seat post assembly may comprise an inner tube; anouter tube telescopically receiving the inner tube; a locking memberengaging the inner tube with the outer tube in at least a firstposition, a second position and a third position; and a stop positivelyarresting relative motion between the tubes at the at least the secondposition and optionally at the first and third positions.

In one embodiment, a method for lowering a seat post assembly maycomprise positioning a controller in an intermediate position; applyinga compressive force to the seat post assembly; and stopping acompression of the seat post at a seat post intermediate positionwithout relieving the compressive force.

In one embodiment, a method of adjusting a seat post assembly that hasan inner tube axially movable within an outer tube, includes: lockingthe inner tube to the outer tube at a first location using a lockingmember that is coupled to the tube; securing the locking member intoengagement with the outer tube using an actuator to lock the inner tubeto the outer tube; moving the actuator against the bias of a biasingmember to release the locking member from engagement with the outer tubeat the first location; and moving the inner tube from the first locationto a second location after releasing the locking member.

The method may comprise biasing a sleeve coupled to the actuator to aposition beneath or behind the locking member to secure the lockingmember into engagement with the outer tube. The method may furthercomprise moving the actuator against the bias of the biasing member torelease the locking member from engagement with the outer tube at thesecond location, and moving the inner tube from the second location to athird location after releasing the locking member.

The locking member may comprise a first plurality of ball members and asecond plurality of ball members, and further comprising urging thefirst plurality of ball members into engagement with the outer tubewhile preventing the second plurality of ball members from engaging theouter tube at the first location. The method may further comprisestopping axial movement of the inner tube relative to the outer tubeusing the second plurality of ball members at a position where the firstplurality of ball members engage the outer tube at the second location.

The method may further comprise urging a third plurality of ball membersinto engagement with the outer tube to rotationally secure the innertube to the outer tube. The method may further comprise controllingactuation of the actuator using a lever assembly comprising a firstlever rotatable through a first angular distance, and a second leverrotatable through half of the first angular distance together with thefirst lever. The method may further comprise rotating the first leverthrough half of the first angular rotation and into contact with thesecond lever to thereby actuate the actuator to release the lockingmember for movement from the first location to the second location onthe outer tube. The method may further comprise rotation of the firstand second levers together through the other half of the first angulardistance to thereby actuate the actuator to release the locking memberfor movement from the second location to a third location on the outertube.

While the foregoing is directed to embodiments of the invention, otherand further embodiments of the invention may be devised withoutdeparting from the basic scope thereof, and the scope thereof isdetermined by the claims that follow.

What we claim is:
 1. A lever assembly for shifting a suspension systembetween at least two positions, said lever assembly comprising: asupport member, said support member comprising an adjustably securedopening at a first distal end and a support structure at an oppositedistal end; a housing, said housing rotatably supporting a first leverand a second lever for manual operation by a user, said housingmountable directly to said support structure to orient said first leverand said second lever in a first orientation and inversely mountable tosaid support structure to orient said first lever and said second leverin a second orientation; at least one cable coupled with the first leverand with said suspension system; said first lever configured to rotatethrough a first angular distance to pull an amount of cable necessary tocause an adjustment to said suspension component; and said second leverconfigured to rotate through only a portion of the first angulardistance of said first lever, wherein a portion of said second leveroverlaps a portion of said first lever, and wherein a force applied tosaid second lever in one direction causes the first lever to move in asame direction at a same time.
 2. The lever assembly of claim 1, whereinsaid at least two positions of said suspension system comprises threepositions such that said suspension system is shiftable between saidthree positions.
 3. The lever assembly of claim 2, wherein said threepositions of said suspension system correspond to extended, retractedand intermediate positions of said first lever.
 4. The lever assembly ofclaim 1, wherein said suspension system is shifted with said at leastone cable.
 5. A lever assembly for shifting a bicycle suspension betweenat least two positions, said lever assembly comprising: a supportmember, said support member comprising an adjustably secured opening ata first distal end and a support structure at an opposite distal end; ahousing, said housing rotatably supporting a first and a second leverfor manual manipulation, said housing mountable directly to said supportstructure to orient said first lever and said second lever in a firstorientation and inversely mountable to said support structure to orientsaid first lever and said second lever in a second orientation; at leastone cable coupled with the first lever and with said bicycle suspensionwherein manipulation of said first lever causes an adjustment to saidbicycle suspension, wherein said first lever is configured to rotatethrough a first angular distance to pull a full amount of cablenecessary to adjust said bicycle suspension between its lowest positionto its highest position and wherein said second lever is configured torotate through only a portion of said first angular distance of saidfirst lever, wherein a force applied to said second lever is onedirection causes said first lever to move in a same direction at a sametime.